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/*
* Project: HARTIK (HA-rd R-eal TI-me K-ernel)
*
* Coordinators: Giorgio Buttazzo <giorgio@sssup.it>
* Gerardo Lamastra <gerardo@sssup.it>
*
* Authors : Massimiliano Giorgi <massy@hartik.sssup.it>
* (see authors.txt for full list of hartik's authors)
*
* ReTiS Lab (Scuola Superiore S.Anna - Pisa - Italy)
*
* http://www.sssup.it
* http://retis.sssup.it
* http://hartik.sssup.it
*/
/*
* Copyright (C) 1999 Massimiliano Giorgi
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
/*
* CVS : $Id: dentry.c,v 1.1.1.1 2002-03-29 14:12:50 pj Exp $
*
* File: $File$
* Revision: $Revision: 1.1.1.1 $
* Last update: $Date: 2002-03-29 14:12:50 $
*/
#include <fs/util.h>
#include <fs/types.h>
#include <fs/assert.h>
#include "fs.h"
#include "super.h"
#include "superop.h"
#include "dentry.h"
#include "dentryop.h"
#include "inode.h"
#include "inodeop.h"
#include "fsconst.h"
#include "mutex.h"
#include "debug.h"
/*
* DEBUG
*/
/* if defined:
* a short message is printed on console when a task go in/out of
* functions dentry_find() & dentry_unlock()
* (after and before the lock/unlock of the mutex!)
*/
#define DEBUGFINDUNLOCK KERN_DEBUG
#undef DEBUGFINDUNLOCK
#ifdef DEBUGFINDUNLOCK
#define printdd(fmt,pid) kern_printf(fmt,pid)
#else
#define printdd(fmt,pid)
#endif
/* if you modify this you must modify MAXINODE */
#define MAXDENTRY 128
static __fs_mutex_t mutex
;
static __fs_fastmutex_t mutexreq
;
static struct dentry
*freelist
;
//static struct dentry *leaflist;
static struct dentry direntry
[MAXDENTRY
];
static struct dentry
*root_direntry
=NULL
;
#ifdef FSMUTEXCHECK
void debug_dump_dentry_mutex
(void)
{
//printk(KERN_DEBUG "dentry mutex: %i",(int)mutex);
//printk(KERN_DEBUG "dentry mutex req: %i",(int)mutexreq);
}
//static __fs_mutex_t regmutex;
//static __fs_mutex_t regmutexreq;
int debug_check_dentry_mutex
(void)
{
/*
if (mutex!=regmutex) {
printk(KERN_DEBUG "dentry mutex CHANGED! (prev: %i)",regmutex);
return 0;
}
if (mutexreq!=regmutexreq) {
printk(KERN_DEBUG "dentry mutexreq CHANGED! (prev: %i)",regmutexreq);
return 0;
}
*/
return -1;
}
void debug_save_dentry_mutex
(void)
{
//regmutex=mutex;
//regmutexreq=mutexreq;
}
#endif
int dentry_init
(void)
{
int i
;
__fs_mutex_init
(&mutex
);
__fs_fastmutex_init
(&mutexreq
);
#ifdef FSMUTEXCHECK
debug_save_dentry_mutex
();
#endif
freelist
=direntry
;
for (i
=0;i
<MAXDENTRY
;i
++) {
memset(direntry
+i
,0,sizeof(struct dentry
));
magic_set
(direntry
[i
].
magic,DENTRY_MAGIC
);
direntry
[i
].
d_next=direntry
+i
+1;
direntry
[i
].
d_lock=-1;
}
direntry
[MAXDENTRY
-1].
d_next=NULL
;
return 0;
}
static __inline__
struct dentry
*__get_dentry
(void)
{
struct dentry
*den
;
if (freelist
==NULL
) return NULL
;
den
=freelist
;
freelist
=den
->d_next
;
_assert
(den
->d_lock
==-1);
magic_assert
(den
->magic
,DENTRY_MAGIC
,"get_dentry: dentry MAGIC failed!");
den
->d_lock
=0;
return den
;
}
/* get a dentry from the free queue */
struct dentry
*get_dentry
(void)
{
struct dentry
*den
;
__fs_fastmutex_lock
(&mutexreq
);
den
=__get_dentry
();
__fs_fastmutex_unlock
(&mutexreq
);
return den
;
}
static __inline__
void __free_dentry
(struct dentry
*den
)
{
_assert
(den
>=direntry
&&den
<direntry
+MAXDENTRY
);
_assert
(den
->d_lock
==0);
magic_assert
(den
->magic
,DENTRY_MAGIC
,"free_dentry: dentry MAGIC failed!");
den
->d_lock
=-1;
den
->d_next
=freelist
;
freelist
=den
;
}
/* insert dentry into the free queue */
void free_dentry
(struct dentry
*den
)
{
__fs_fastmutex_lock
(&mutexreq
);
__free_dentry
(den
);
__fs_fastmutex_unlock
(&mutexreq
);
}
static void __insert_dentry
(struct dentry
*den
, struct dentry
*parent
)
{
_assert
(den
>=direntry
&&den
<direntry
+MAXDENTRY
);
magic_assert
(den
->magic
,DENTRY_MAGIC
,"insert_dentry: dentry MAGIC failed!");
den
->d_acc
=gettimek
();
den
->d_parent
=parent
;
den
->d_child
=NULL
;
den
->d_prev
=NULL
;
den
->d_next
=parent
->d_child
;
if (parent
->d_child
!=NULL
)
parent
->d_child
->d_prev
=den
;
parent
->d_child
=den
;
}
/* insert a dentry into the tree */
void insert_dentry
(struct dentry
*den
, struct dentry
*parent
)
{
__fs_mutex_lock
(&mutex
);
__insert_dentry
(den
,parent
);
__fs_mutex_unlock
(&mutex
);
}
static void __remove_dentry_only
(struct dentry
*den
)
{
_assert
(den
>=direntry
&&den
<direntry
+MAXDENTRY
);
magic_assert
(den
->magic
,DENTRY_MAGIC
,"remove_dentry: dentry MAGIC failed!");
_assert
(den
->d_lock
==0);
if (den
->d_prev
!=NULL
)
den
->d_prev
->d_next
=den
->d_next
;
else
den
->d_parent
->d_child
=den
->d_next
;
if (den
->d_next
!=NULL
)
den
->d_next
->d_prev
=den
->d_prev
;
}
static __inline__
void __remove_dentry
(struct dentry
*den
)
{
__remove_dentry_only
(den
);
unlock_inode
(den
->d_inode
);
}
/* remove a dentry from the tree */
void remove_dentry
(struct dentry
*den
)
{
__fs_mutex_lock
(&mutex
);
__remove_dentry
(den
);
__fs_mutex_unlock
(&mutex
);
}
/* find the oldest dentry into the tree */
/*
* (potrebbe essere fatto in maniera non ricorsiva usando un
* puntatore alle foglie e scandendo questa lista invece di visitare
* tutto l'albero!)
*
* si potrebbe usare un task NRT periodico per mantenere liberi (se
* possibile l'X% delle dentry libere.
*/
static struct dentry
*__recurse
(struct dentry
*den
, struct dentry
*act
)
{
while (den
!=NULL
) {
if (den
->d_child
!=NULL
) {
act
=__recurse
(den
->d_child
,act
);
} else {
if (den
->d_lock
==0) {
if (act
==NULL
)
act
=den
;
else {
if (den
->d_acc
<act
->d_acc
)
act
=den
;
}
}
}
den
=den
->d_next
;
}
return act
;
}
struct dentry
*__purge_dentry
(void)
{
struct dentry
*act
;
act
=__recurse
(root_direntry
,NULL
);
if (act
!=NULL
) __remove_dentry
(act
);
return act
;
}
/* find & remove the oldest dentry from the tree */
struct dentry
*purge_dentry
(void)
{
struct dentry
*act
;
__fs_mutex_lock
(&mutex
);
act
=__purge_dentry
();
__fs_mutex_unlock
(&mutex
);
return act
;
}
struct dentry
*__catch_dentry
(void)
{
struct dentry
*den
;
den
=__get_dentry
();
if (den
==NULL
) den
=__purge_dentry
();
return den
;
}
/* get a dentry by searching into the free space or purging an old one */
/*
static struct dentry *catch_dentry(void)
{
struct dentry *den;
__fs_mutex_lock(&mutex);
den=__catch_dentry();
__fs_mutex_unlock(&mutex);
return den;
}
*/
/*---------------------*/
int set_root_dentry
(struct super_block
*sb
)
{
struct dentry
*den
;
__fs_mutex_lock
(&mutex
);
if (sb
==NULL
) {
_assert
(root_direntry
!=NULL
);
root_direntry
->d_lock
--;
_assert
(root_direntry
->d_lock
==1);
root_direntry
=NULL
;
__fs_mutex_unlock
(&mutex
);
return 0;
}
_assert
(root_direntry
==NULL
);
__fs_mutex_unlock
(&mutex
);
den
=get_dentry
();
if (den
==NULL
) return -1;
den
->d_next
=NULL
;
den
->d_prev
=NULL
;
den
->d_parent
=NULL
;
den
->d_child
=NULL
;
den
->d_acc
=0;
den
->d_name.
nameptr=ROOTDIRNAME
;
den
->d_op
=sb
->sb_dop
;
den
->d_sb
=sb
;
den
->d_inode
=sb
->sb_root
;
den
->d_lock
=1;
sb
->sb_droot
=den
;
root_direntry
=den
;
return 0;
}
struct dentry
*get_root_dentry
(void)
{
_assert
(root_direntry
!=NULL
);
return root_direntry
;
}
#ifdef DEBUG_FIND_DUMP
static void dump_dentry
(struct dentry
*ptr
)
{
printk7
(KERN_DEBUG
"dentry dump:");
printk7
(KERN_DEBUG
" name : %s",QSTRNAME
(&ptr
->d_name
));
printk7
(KERN_DEBUG
" lock : %i",ptr
->d_lock
);
printk7
(KERN_DEBUG
" inode: %i",ptr
->d_inode
->i_st.
st_ino);
}
#else
#define dump_dentry(x)
#endif
/*--------------*/
/*
* flags for createflags:
* DENTRY_NOCREATE -> can't create a new inode
* DENTRY_CANCREATE -> an inode (only the last) can be created
* DENTRY_MUSTCREATE -> the last inode MUST be created (it must no exist)
*
* return flags for createflags:
* DENTRY_CREATED -> the last inode has been created
* DENTRY_EXIST -> (error) the last inode already exist
*
* return NULL on error (not found or DENTRY_EXIST)
*
* NB:
* if createflag is NULL a DENTRY_NOCREATE is assumed
* 'act' can be NULL if pathname is an absolute path
*/
struct dentry
*find_dentry_from_ext
(struct dentry
*act
,
char *pathname
,
int *createflag
)
{
struct dentry
*ptr
;
struct dentry
*den
;
struct inode
*ino
;
struct qstr str
;
char *sp
;
char *s
;
int found
,created
;
/* too much 'goto' :-( and 'if' */
sp
=pathname
;
if (*pathname
==DIRDELIMCHAR
) {
act
=root_direntry
;
sp
++;
}
if (act
==NULL
) return NULL
;
printdd
("°f<%i>",exec_shadow
);
__fs_mutex_lock
(&mutex
);
printdd
("±f<%i>",exec_shadow
);
if (*sp
=='\0') goto END0
;
created
=0;
found
=1;
while (found
) {
s
=strchr(sp
,DIRDELIMCHAR
);
if (s
!=NULL
) *s
='\0';
printk7
("dentry find: searching for %s...",sp
);
/* for handle special directory entry "." and ".." */
if (*sp
=='.') {
if (*sp
=='\0') {
/* found "." special directory */
printk7
("dentry find: special directory entry '.'");
found
=1;
if (s
==NULL
) goto END0
;
*s
=DIRDELIMCHAR
;
sp
=s
+1;
s
=strchr(sp
,DIRDELIMCHAR
);
continue;
}
if (*sp
=='.') {
if (*sp
=='\0') {
/* found ".." special directory */
printk7
("dentry find: special directory entry '..'");
found
=1;
if (act
->d_parent
!=NULL
) act
=act
->d_parent
;
if (s
==NULL
) goto END0
;
*s
=DIRDELIMCHAR
;
sp
=s
+1;
s
=strchr(sp
,DIRDELIMCHAR
);
continue;
}
}
}
ptr
=act
->d_child
;
found
=0;
str.
nameptr=sp
;
while (ptr
!=NULL
) {
if (ptr
->d_op
->d_compare
(ptr
,&ptr
->d_name
,&str
)==0) {
printk7
("dentry find: found!");
found
=1;
act
=ptr
;
if (s
==NULL
) goto END0
;
*s
=DIRDELIMCHAR
;
sp
=s
+1;
s
=strchr(sp
,DIRDELIMCHAR
);
break;
}
ptr
=ptr
->d_next
;
}
}
printk7
("dentry find: NOT found!");
for (;;) {
den
=__catch_dentry
();
if (den
==NULL
) {
if (s
!=NULL
) *s
=DIRDELIMCHAR
;
printk7
("dentry find: can't have new struct dentry!");
act
=NULL
;
goto END1
;
}
den
->d_acc
=0;
den
->d_name.
nameptr=NULL
;
strcpy(den
->d_name.
name,sp
);
den
->d_lock
=0;
den
->d_op
=act
->d_op
;
den
->d_sb
=act
->d_sb
;
printk7
("dentry find: looking up for %s....",sp
);
dump_dentry
(act
);
ino
=act
->d_inode
->i_op
->lookup
(act
->d_inode
,den
);
printk7
("dentry find: end looking");
if (ino
==NULL
) {
printk7
("dentry find: NOT found!");
if (s
!=NULL
) *s
=DIRDELIMCHAR
;
if (createflag
==NULL
) {
__free_dentry
(den
);
act
=NULL
;
goto END1
;
}
if ((s
==NULL
)&&(*createflag
&DENTRY_CANCREATE
)) {
printk7
("dentry find: check for read-only fs");
if (!(act
->d_sb
->sb_mopts.
flags&MOUNT_FLAG_RW
)) {
printk7
("dentry find: read-only fs.. creating new inode fails");
__free_dentry
(den
);
act
=NULL
;
goto END1
;
}
printk7
("dentry find: try to create a new inode");
ino
=act
->d_inode
->i_op
->create
(act
->d_inode
,den
);
if (ino
==NULL
) {
printk7
("dentry find: inode creation fail");
__free_dentry
(den
);
act
=NULL
;
goto END1
;
}
printk7
("dentry find: new inode created");
created
=1;
} else {
__free_dentry
(den
);
act
=NULL
;
goto END1
;
}
}
den
->d_inode
=ino
;
insert_inode
(ino
);
printk7
("dentry find: found!");
__insert_dentry
(den
,act
);
act
=den
;
if (s
==NULL
) goto END2
;
sp
=s
+1;
*s
=DIRDELIMCHAR
;
s
=strchr(sp
,DIRDELIMCHAR
);
if (s
!=NULL
) *s
='\0';
}
/* for safety */
_assert
(0==-1);
END0
:
/* 'if found' we are here */
if (createflag
!=NULL
) {
*createflag
&=~DENTRY_CREATEMASK
;
if (*createflag
&DENTRY_MUSTCREATE
) {
_assert
(act
!=NULL
);
*createflag
|=DENTRY_EXIST
;
act
=NULL
;
}
}
goto END
;
END1
:
/* 'if error' we are here */
_assert
(act
==NULL
);
if (createflag
!=NULL
) *createflag
&=~DENTRY_CREATEMASK
;
goto END
;
END2
:
/* 'if ok' (found or created) we are here */
_assert
(act
!=NULL
);
if (createflag
!=NULL
) {
if (created
) {
*createflag
&=~DENTRY_CREATEMASK
;
*createflag
|=DENTRY_CREATED
;
} else if ((*createflag
&DENTRY_MUSTCREATE
)==DENTRY_MUSTCREATE
) {
*createflag
&=~DENTRY_CREATEMASK
;
*createflag
|=DENTRY_EXIST
;
act
=NULL
;
} else
*createflag
&=~DENTRY_CREATEMASK
;
}
goto END
;
END
:
if (act
!=NULL
) act
->d_lock
++;
printdd
("²f<%i>",exec_shadow
);
__fs_mutex_unlock
(&mutex
);
printdd
("Ûf<%i>",exec_shadow
);
return act
;
}
void unlock_dentry
(struct dentry
*den
)
{
printdd
("°u<%i>",exec_shadow
);
__fs_mutex_lock
(&mutex
);
printdd
("±u<%i>",exec_shadow
);
_assert
(den
>=direntry
&&den
<direntry
+MAXDENTRY
);
if (den
->d_lock
<=0) {
printk
(KERN_DEBUG
"unlock_dentry on %s",QSTRNAME
(&den
->d_name
));
}
_assert
(den
->d_lock
>0);
den
->d_lock
--;
//if (den->d_lock==0) {
// _assert(den->d_inode!=NULL);
// unlock_inode(den->d_inode);
//}
printdd
("²u<%i>",exec_shadow
);
__fs_mutex_unlock
(&mutex
);
printdd
("Ûu<%i>",exec_shadow
);
}
/*
*
*/
static void __print_name
(struct dentry
*act
,char *buffer
)
{
if (act
->d_parent
==NULL
) return;
__print_name
(act
->d_parent
,buffer
);
strcat(buffer
,ROOTDIRNAME
);
strcat(buffer
,QSTRNAME
(&act
->d_name
));
return;
}
static char *print_name
(struct dentry
*act
)
{
static char buffer
[1024];
buffer
[0]='\0';
__print_name
(act
,buffer
);
return buffer
;
}
void getfullname_dentry
(struct dentry
*act
, char *buffer
, int size
)
{
_assert
(act
>=direntry
&&act
<direntry
+MAXDENTRY
);
magic_assert
(act
->magic
,DENTRY_MAGIC
,
"getfullname_dentry: dentry MAGIC failed!");
buffer
[0]='\0';
__print_name
(act
,buffer
);
_assert
(strlen(buffer
)<size
);
}
static void visit_tree
(struct dentry
*act
)
{
struct dentry
*ptr
;
if (act
==root_direntry
) printk
(KERN_DEBUG
" %s",ROOTDIRNAME
);
else { char *s
=print_name
(act
); printk
(KERN_DEBUG
" %s",s
);}
ptr
=act
->d_child
;
while (ptr
!=NULL
) {
visit_tree
(ptr
);
ptr
=ptr
->d_next
;
}
return;
}
void dump_dentry_tree
(void)
{
printk
(KERN_DEBUG
"DTREE dump");
visit_tree
(root_direntry
);
}
/*
*
*/
#ifdef DEBUGPURGECHILD
#define dprint(fmt,args...) printk(fmt,##args)
#else
#define dprint(fmt,args...)
#endif
static __inline__
int __purgeallchilds_mg
(struct dentry
*de
)
{
int ret
;
struct dentry
*ptr
,*ptr2
,*ptr3
;
dprint
(KERN_DEBUG
"START mg purgechild");
{
#ifdef DEBUGPURGECHILD
char *s
=print_name
(de
);
dprint
(KERN_DEBUG
"for %s",s
);
#endif
}
/*
* Phase 1
* purge all childs (if possible!)
*/
ptr
=de
->d_child
;
ret
=0;
/* why these? I do not want to use recursion... (or goto statement)*/
for (;;) {
/* if there is a child... continue using the child's chain */
if (ptr
->d_child
!=NULL
) {
ptr
=ptr
->d_child
;
continue;
}
/* if a child dentry is locked... can't continue! */
if (ptr
->d_lock
) {
#ifdef DEBUGPURGECHILD
char *s
=print_name
(ptr
);
dprint
(KERN_DEBUG
"%s is locked!!!",s
);
#endif
ret
=-1;
break;
}
/* purge this dentry */
ptr2
=ptr
->d_next
;
ptr3
=ptr
->d_parent
;
dprint
(KERN_DEBUG
"%s destroy",QSTRNAME
(&ptr
->d_name
));
ret
=destroy_inode
(ptr
->d_inode
);
if (ret
) break;
__remove_dentry_only
(ptr
);
/* if there is not another child... continue with the parent */
if (ptr2
==NULL
) {
ptr
=ptr3
;
if (ptr
==de
) break;
continue;
}
/* continue with next child */
ptr
=ptr2
;
}
dprint
(KERN_DEBUG
"END mg purgechild");
return ret
;
}
static __inline__
int __purgeallchilds_pj
(struct dentry
*x
)
{
struct dentry
*p
,*q
;
dprint
(KERN_DEBUG
"START pj purgechild");
p
= x
->d_child
;
q
= NULL
;
for(;;) {
/* scorro i figli */
while(p
) {
q
= p
;
p
= p
->d_next
;
}
if (q
== x
) {
dprint
(KERN_DEBUG
"END pj purgechild");
return 0; /* finito */
}
if (q
->d_child
) {
p
= q
->d_child
;
q
= NULL
;
}
else {
/* sono su un nodo senza figli */
/* q punta al nodo */
if (q
->d_prev
)
{ /* non e' il primo figlio */
q
= q
->d_prev
;
if (q
->d_next
->d_lock
) {
dprint
(KERN_DEBUG
"%s is locked",
QSTRNAME
(&q
->d_next
->d_name
));
return -1;
}
if (destroy_inode
(q
->d_next
->d_inode
)) {
dprint
(KERN_DEBUG
"error destroing %s",
QSTRNAME
(&q
->d_next
->d_name
));
return -1;
}
dprint
(KERN_DEBUG
"removing %s",QSTRNAME
(&q
->d_next
->d_name
));
__remove_dentry_only
(q
->d_next
);
q
->d_next
= NULL
;
p
= NULL
;
}
else {
/* e' il primo figlio */
q
= q
->d_parent
;
if (q
->d_child
->d_lock
) {
dprint
(KERN_DEBUG
"%s is locked",
QSTRNAME
(&q
->d_child
->d_name
));
return -1;
}
if (destroy_inode
(q
->d_child
->d_inode
)) {
dprint
(KERN_DEBUG
"error destroing %s",
QSTRNAME
(&q
->d_child
->d_name
));
return -1;
}
dprint
(KERN_DEBUG
"removing %s",QSTRNAME
(&q
->d_child
->d_name
));
__remove_dentry_only
(q
->d_child
);
q
->d_child
= NULL
;
p
= NULL
;
}
}
}
}
#define __purgeallchilds(de) __purgeallchilds_mg(de)
int mount_dentry
(struct super_block
*sb
, struct dentry
*de
)
{
int ret
;
printk9
("START mount_dentry()!");
printk9
("for %s",QSTRNAME
(&de
->d_name
));
_assert
(de
!=NULL
);
_assert
(sb
!=NULL
);
__fs_mutex_lock
(&mutex
);
printk9
("locked and ready");
if (de
->d_lock
>1) {
printk9
("LOCKED!");
/* someone is using this dentry! */
__fs_mutex_unlock
(&mutex
);
return -1;
}
/*
* Phase 1
*/
/* purge all childs (if possible) */
if (de
->d_child
!=NULL
) {
ret
=__purgeallchilds
(de
);
if (ret
) {
printk9
("PURGECHILD!");
__fs_mutex_unlock
(&mutex
);
return ret
;
}
}
/*
* Phase 2
*/
ret
=destroy_inode
(de
->d_inode
);
if (ret
) {
printk9
("DESTROY INODE!");
__fs_mutex_unlock
(&mutex
);
return ret
;
}
de
->d_op
=sb
->sb_dop
;
de
->d_inode
=sb
->sb_root
;
de
->d_sb
=sb
;
sb
->sb_droot
=de
;
__fs_mutex_unlock
(&mutex
);
printk9
("END mount_dentry()!");
return 0;
}
int umount_dentry
(struct super_block
*sb
)
{
struct dentry
*de
;
int res
;
printk9
("START umount_dentry()");
__fs_mutex_lock
(&mutex
);
_assert
(sb
!=NULL
);
_assert
(sb
->sb_droot
!=NULL
);
if (sb
->sb_droot
->d_child
!=NULL
) {
res
=__purgeallchilds
(sb
->sb_droot
);
if (res
) {
printk9
("PURGING CHILD!");
__fs_mutex_unlock
(&mutex
);
return res
;
}
}
printk9
("umount_dentry: phase 1");
de
=sb
->sb_droot
;
_assert
(de
->d_lock
>0);
if (de
->d_lock
!=1) {
printk9
("LOCK COUNT! (%i)",de
->d_lock
);
__fs_mutex_unlock
(&mutex
);
return -1;
}
de
->d_lock
--;
printk9
("umount_dentry: phase 2");
__remove_dentry_only
(de
);
destroy_inode
(de
->d_inode
);
__free_dentry
(de
);
printk9
("umount_dentry: phase 3");
sb
->sb_droot
=NULL
;
sb
->sb_root
=NULL
;
__fs_mutex_unlock
(&mutex
);
printk9
("END umount_dentry()!");
return 0;
}
int unlink_dentry
(struct dentry
*d
)
{
struct inode
*in
;
int res
;
printkd
("unlink_dentry: START");
__fs_mutex_lock
(&mutex
);
if (d
->d_lock
!=1) return EBUSY
;
in
=d
->d_inode
;
printkd
("unlink_dentry: dentry ok");
__rwlock_wrlock
(&in
->i_lock
);
printkd
("unlink_dentry: locked inode");
res
=in
->i_op
->unlink
(d
);
printkd
("unlink_dentry: inode unlinked from dentry");
if (res
==0&&in
->i_st.
st_nlink==0) {
printkd
("unlink_dentry: no more links erasing inode");
erase_inode
(in
);
}
__rwlock_wrunlock
(&in
->i_lock
);
printkd
("unlink_dentry: unlocked inode");
if (res
==0) {
d
->d_lock
--;
__remove_dentry_only
(d
);
printkd
("unlink_dentry: dentry unlinked");
}
__fs_mutex_unlock
(&mutex
);
printkd
("unlink_dentry: END");
return -res
;
}